Systems And Methods For Use With Orthogonal Frequency Division Multiplexing

ABSTRACT

Systems and methods are provided for enabling H-ARQ communication between a base station and one or more wireless terminals. Methods for enabling incremental redundancy (IR) based H-ARQ, Chase based H-ARQ and Space-Time Code combining (STC) based H-ARQ between devices for down⋅link and up-link direction transmissions are provided in the form of an information element (IE) for use with a Normal MAP convention as currently accepted in the draft version standard of IEEE 802.16. In addition, embodiments of the invention provide a resource management scheme to protect a network from abuse of resources from a wireless terminal not registered with the network. Components of the down-link and up-link mapping components of a data frame transmitted from the base station to one or more wireless terminals included messages that are readable by all wireless terminals as well as some messages that are encrypted and only readable by wireless terminals that are authenticated as being registered with the network.

RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional PatentApplication No. 60/624,343 filed on Nov. 2, 2004, which is herebyincorporated in its entirety.

FIELD OF THE INVENTION

The invention generally relates to the field of wireless communications,more specifically to systems and methods for broadband mobile wirelessmetropolitan networks including networks operating according to the IEEE802.16(e) standard.

BACKGROUND OF THE INVENTION

Orthogonal frequency division multiplexing (OFDM) is a form ofmultiplexing that distributes data over a number of carriers that have avery precise spacing in the frequency domain. The precise spacing of thecarriers provides several benefits such as high spectral efficiency,resiliency to radio frequency interference and lower multi-pathdistortion. Due to its beneficial properties and superior performance inmulti-path fading wireless channels, OFDM has been identified as auseful technique in the area of high data-rate wireless communication,for example wireless metropolitan area networks (MAN). Wireless MAN arenetworks to be implemented over an air interface for fixed, portable,and mobile broadband access systems. A standard being developed for usewith OFDM and wireless networks is IEEE 802.16.

In early versions of the standard for IEEE 802.16 there was no acceptedmanner for hybrid automatic repeat request (H-ARQ) operation. Theaccepted down-link (DL) and up-link (UL) allocation mapping (or MAP)information element (IE) structure had no IE formats that enabled H-ARQcommunication between devices.

Also, in more recent versions of the IEEE 802.16 standard, a bandwidth(BW) request media access control (MAC) header is used for a registeredwireless terminal to request UL bandwidth. However, there is noauthentication field attached to this header. As no formal registrationto a network is needed to request resources from the network, anymalicious terminal can monitor a UL-MAP message sent by a base stationand determine an OFDM region assigned for sending a BW request code(taking OFDMA PHY as an example) and then sending the BW request headerusing a CID (connection identification) assigned to a wireless terminalthat is registered with the network. Such a malicious wireless terminalmay significantly interfere with normal operation of a network operatingin compliance with the IEEE 802.16 standard.

A need exists for improved systems and methods to overcome theseproblems.

SUMMARY OF THE INVENTION

According to a first aspect of the invention there is provided a methodin a base station for operating a hybrid automatic repeat request(H-ARQ) enabled OFDM (orthogonal frequency multiplexing) connection witha wireless terminal, the method comprising: the base station sending thewireless terminal an indication of a total number of transmissionresource allocations to be made in a data frame; for each transmissionresource allocation, the base station sending the wireless terminallocation information of where a H-ARQ transmission is located in thedata frame; sending an identification of a channel on which the H-ARQtransmission is being transmitted; sending an identification of theH-ARQ transmission.

In some embodiments, the H-ARQ enabled connection is an incrementalredundancy (IR) based H-ARQ enabled connection.

In some embodiments, the method is for use with a MIMO enabled wirelessterminal and for enabling the H-ARQ transmission in a down-link (DL)direction from the base station to the wireless terminal, the methodfurther comprising for each transmission resource allocation, the basestation: sending a total number of data streams to be used fortransmitting to the wireless terminal; and sending the identification ofthe channel and sending the identification of the H-ARQ transmission foreach resource allocation are performed for each data stream, whereinsending the identification of the H-ARQ transmission comprises sendingan indication of when a new packet, which includes the H-ARQtransmission, is being transmitted and sending an identification of asub-packet, which includes at least a portion of the H-ARQ transmission,that is being transmitted.

In some embodiments, the H-ARQ enabled connection is a Chase based H-ARQenabled connection.

In some embodiments, the method is for use with a MIMO enabled wirelessterminal and for enabling the H-ARQ transmission in a down-link (DL)direction from the base station to the wireless terminal, the methodfurther comprising for each assignment, the base station: sending atotal number of data streams to be used for transmitting to the wirelessterminal; and sending the identification of the channel and sending theidentification of the H-ARQ transmission for each resource allocationare performed for each data stream, wherein sending the identificationof the H-ARQ transmission comprises sending an indication of atransmission count that indicates a number of times the H-ARQtransmission has been transmitted including the current transmission.

In some embodiments, the method is for use with a MIMO enabled wirelessterminal and for enabling the H-ARQ transmission in an up-link (UL)direction from the wireless terminal to the base station, the methodfurther comprising for each transmission resource allocation, the basestation: sending an indication of whether the H-ARQ transmission fromthe wireless terminal to the base station is to be performed usingcollaborative spatial multiplexing or not; if the H-ARQ transmissionfrom the wireless terminal to the base station is not performed usingcollaborative spatial multiplexing, the base station sending anindication of when a new packet, which includes the H-ARQ transmission,is being transmitted and sending an identification of a sub-packet,which includes at least a portion of the H-ARQ transmission, that isbeing transmitted; if the H-ARQ transmission from the wireless terminalto the base station is performed using collaborative spatialmultiplexing, for each wireless terminal used in the collaborativespatial multiplexing, the base station sending an indication of when thenew packet, which includes the H-ARQ transmission, is being transmittedand sending an identification of the sub-packet, which includes at leasta portion of the H-ARQ transmission, that is being transmitted.

In some embodiments, the method is for use with a MIMO enabled wirelessterminal and for enabling the H-ARQ transmission in an up-link (UL)direction from the wireless terminal to the base station, the methodfurther comprising for each transmission resource allocation, the basestation: sending an indication of whether the H-ARQ transmission fromthe wireless terminal to the base station is to be performed usingcollaborative spatial multiplexing or not; if the H-ARQ transmissionfrom the wireless terminal to the base station is not performed usingcollaborative spatial multiplexing, the base station sending anindication of a transmission count that indicates a current number oftimes the transmit information has been transmitted including thecurrent transmission; if the H-ARQ transmission from the wirelessterminal to the base station is performed using collaborative spatialmultiplexing, the base station sending an indication of a transmissioncount that indicates a number of times the transmit information has beentransmitted including the current transmission for each wirelessterminal used in the collaborative spatial multiplexing.

In some embodiments, if the transmission does not use collaborativespatial multiplexing the base station further sends an indication ofwhether space-time transmit diversity (STTD) or spatial multiplexing(SM) is used for transmitting the H-ARQ transmission.

In some embodiments, sending an identification of the H-ARQ transmissionfor a non-MIMO enabled wireless terminal comprises sending an indicationof when a new packet, which includes the H-ARQ transmission, is beingtransmitted and sending an identification of a sub-packet, whichincludes at least a portion of the H-ARQ transmission, that is beingtransmitted.

In some embodiments, sending an identification of the H-ARQ transmissionfor a non-MIMO enabled wireless terminal comprises sending an indicationof a transmission count that indicates a number of times the transmitinformation has been transmitted including the current transmission.

In some embodiments, sending the wireless terminal location informationcomprises either sending both an indication of an initial starting pointof a region for the transmission resource allocation in the data frameand an indication of the size of the region for the transmissionresource allocation in the data frame, or sending an indication of aduration of a region for the transmission resource allocation in thedata frame.

According to a second aspect of the invention, there is provided amethod in a multi-antenna enabled base station for operating a hybridautomatic repeat request (H-ARQ) enabled OFDM (orthogonal frequencymultiplexing) connection with a wireless terminal, the methodcomprising: the base station sending the wireless terminal an indicationof the number of transmission resource allocations to be made in a dataframe; for each resource allocation the base station: sending anindication of a transmission count that indicates a number of times theH-ARQ transmission has been transmitted from the base station to thewireless terminal including the current transmission, if it is a firstattempt at sending the H-ARQ transmission; sending the wireless terminalpositional information of where H-ARQ transmission is located in thedata frame; sending an identification of a channel on which the H-ARQtransmission is being transmitted.

In some embodiments, the H-ARQ enabled connection with a wirelessterminal comprises a connection for transmission in either a down-link(DL) direction from the base station to the wireless terminal or anup-link (UL) direction from the wireless terminal to the base station.

In some embodiments, a transmission matrix used to send the H-ARQtransmission to the wireless terminal is determined by the number ofantennas in the multi-antenna enabled base station.

In some embodiments, the base station sending information to thewireless terminals comprises the base station sending the information inan information element (IE) of the data frame, the data frametransmitted from the base station to the at least one wireless terminal.

In some embodiments, the base station sending the information in an IEcomprises the base station sending the IE as a plurality of fields inthe data frame, each field comprising one or more bits.

According to a third aspect of the invention, there is provided methodin a wireless terminal for operating a hybrid automatic repeat request(H-ARQ) enabled OFDM (orthogonal frequency multiplexing) connection witha base station, the method comprising: the wireless terminal receivingan indication of a total number of transmission resource allocations tobe made in a data frame; for each transmission resource allocation, thewireless terminal: receiving the wireless terminal location informationof where a H-ARQ transmission is located in the data frame; receiving anidentification of a channel on which the H-ARQ transmission is beingtransmitted; receiving an identification of the H-ARQ transmission.

In some embodiments, the H-ARQ enabled connection is an incrementalredundancy (IR) based H-ARQ enabled connection or a Chase based H-ARQenabled connection.

According to a fourth aspect of the invention, there is provided amethod for use in a base station for resource management of resources ina network, the method comprising transmitting in a frame: at least onenon-encrypted mapping message that is readable by any wireless terminalto aid in a wireless terminal initially accessing the network; at leastone encrypted mapping message that is readable by only a wirelessterminal authenticated as being registered with the network, the atleast one encrypted mapping message comprising information pertaining toresource management of the network.

In some embodiments, the at least one non-encrypted mapping message is adown-link mapping message comprising at least one pointer to othernon-encrypted mapping messages and/or at least one encrypted mappingmessage.

In some embodiments, the at least one non-encrypted mapping message isan up-link mapping message comprising at least one pointer to regions inthe frame used for transmission from the wireless terminal to the basestation designated for arranging access to the network.

In some embodiments, the at least one encrypted mapping message is anup-link mapping message comprising pointers to regions in the frame usedfor transmission from the wireless terminal to the base stationdesignated for requesting additional up-link resources in from the basestation.

In some embodiments, the method further comprises after a wirelessterminal has been authenticated as being registered with the network,the base station transmitting an encryption key to the authenticatedwireless terminal to enable encryption and decryption of transmissionsbetween the base station and the wireless terminals.

In some embodiments, the encryption key is an encryption key paircomprising a public encryption key that is known to the base station orany wireless terminal and a private encryption key known only to theregistered wireless terminal to which it is assigned.

According to a fifth aspect of the invention, there is provided a methodfor use in a wireless terminal for requesting transmission resources ina network from a base station, the method comprising: receiving a dataframe transmitted by the base station providing a first non-encryptedmapping message including a pointer to a second non-encrypted mappingmessage utilized in initially accessing the network; transmitting arequest to the base station to gain access to the network in a portionof an up-link subframe identified by the second non-encrypted mappingmessage; following authentication of the wireless terminal as aregistered wireless terminal with the network by the base station, theauthenticated wireless terminal: receiving an encryption key from thebase station to decrypt encrypted transmissions from the base station;receiving an encrypted mapping message providing a location in theup-link subframe of the data frame in which a resource allocationrequest can be sent by the wireless terminal to the base station;decrypting the encrypted mapping message from the base station; andtransmitting the resource allocation request in an up-link subframe ofthe data frame to the base station; and if the wireless terminal is notauthenticated by the base station to be registered with the network, thewireless terminal is incapable of decrypting encrypted transmissionsfrom the base station identifying where in a subsequent data frame thewireless terminal is allowed to send a resource allocation request.

According to another aspect of the invention, there is provided a basestation adapted to implement embodiments of the inventive methodsdescribed above.

According to a further aspect of the invention, there is provided awireless terminal adapted to implement embodiments of the inventivemethods described above.

Other aspects and features of the present invention will become apparentto those ordinarily skilled in the art upon review of the followingdescription of specific embodiments of the invention in conjunction withthe accompanying figures.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention will now be described withreference to the attached drawings in which:

FIG. 1 is a block diagram of a cellular communication system;

FIG. 2 is a block diagram of an example base station that might be usedto implement some embodiments of the present invention;

FIG. 3 is a block diagram of an example wireless terminal that might beused to implement some embodiments of the present invention;

FIG. 4 is a block diagram of a logical breakdown of an example OFDMtransmitter architecture that might be used to implement someembodiments of the present invention;

FIG. 5 is a block diagram of a logical breakdown of an example OFDMreceiver architecture that might be used to implement some embodimentsof the present invention;

FIG. 6 is a schematic view of an OFDM frame for use with embodimentsprovided by the invention;

FIG. 7 is a signaling diagram for communication between a base stationand a wireless terminal according to an embodiment of the invention;

FIG. 8 is a signaling diagram for communication between a base stationand a wireless terminal according to another embodiment of theinvention;

FIG. 9 is a flow chart for a method for a down-link (DL) direction IRbased H-ARQ transmission scheme according to an embodiment of theinvention;

FIG. 10 is a flow chart for a method for another DL direction IR basedH-ARQ transmission scheme according to an embodiment of the invention;

FIG. 11 is a flow chart for a method for a DL direction Chase basedH-ARQ transmission scheme according to an embodiment of the invention;

FIG. 12 is a flow chart for a method for another DL direction Chasebased H-ARQ transmission scheme according to an embodiment of theinvention;

FIG. 13 is a flow chart for a method for a DL direction STC based H-ARQtransmission scheme according to an embodiment of the invention;

FIG. 14 is a flow chart for a method for an up-link (UL) direction IRbased H-ARQ transmission scheme according to an embodiment of theinvention;

FIG. 15 is a flow chart for a method for another UL direction IR basedH-ARQ transmission scheme according to an embodiment of the invention;

FIG. 16 is a flow chart for a method for a UL direction Chase basedH-ARQ transmission scheme according to an embodiment of the invention;

FIG. 17 is a flow chart for a method for another UL direction Chasebased H-ARQ transmission scheme according to an embodiment of theinvention;

FIG. 18 is a resource management message transmission scheme accordingto the IEEE 802.16(e)/D5 draft version if the IEEE 802.16 standard;

FIG. 19 is a resource management transmission scheme according to anembodiment of the invention; and

FIG. 20 is a flow chart for a method of resource management protectionaccording to an embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For the purposes of providing context for embodiments of the inventionfor use in a communication system, FIG. 1 shows a base stationcontroller (BSC) 10 which controls wireless communications withinmultiple cells 12, which cells are served by corresponding base stations(BS) 14. In general, each base station 14 facilitates communicationsusing OFDM with mobile and/or wireless terminals 16, which are withinthe cell 12 associated with the corresponding base station 14. Themovement of the mobile terminals 16 in relation to the base stations 14results in significant fluctuation in channel conditions. Asillustrated, the base stations 14 and mobile terminals 16 may includemultiple antennas to provide spatial diversity for communications.

A high level overview of the mobile terminals 16 and base stations 14upon which aspects of the present invention are implemented is providedprior to delving into the structural and functional details of thepreferred embodiments. With reference to FIG. 2, a base station 14 isillustrated. The base station 14 generally includes a control system 20,a baseband processor 22, transmit circuitry 24, receive circuitry 26,multiple antennas 28, and a network interface 30. The receive circuitry26 receives radio frequency signals bearing information from one or moreremote transmitters provided by mobile terminals 16 (illustrated in FIG.1). Preferably, a low noise amplifier and a filter (not shown) cooperateto amplify and remove broadband interference from the signal forprocessing. Downconversion and digitization circuitry (not shown) willthen downconvert the filtered, received signal to an intermediate orbaseband frequency signal, which is then digitized into one or moredigital streams.

The baseband processor 22 processes the digitized received signal toextract the information or data bits conveyed in the received signal.This processing typically comprises demodulation, decoding, and errorcorrection operations. As such, the baseband processor 22 is generallyimplemented in one or more digit signal processors (DSPs) orapplication-specific integrated circuits (ASICs). The receivedinformation is then sent across a wireless network via the networkinterface 30 or transmitted to another mobile terminal 16 serviced bythe base station 14.

On the transmit side, the baseband processor 22 receives digitized data,which may represent voice, data, or control information, from thenetwork interface 30 under the control of control system 20, and encodesthe data for transmission. The encoded data is output to the transmitcircuitry 24, where it is modulated by a carrier signal having a desiredtransmit frequency or frequencies. A power amplifier (not shown) willamplify the modulated carrier signal to a level appropriate fortransmission, and deliver the modulated carrier signal to the antennas28 through a matching network (not shown). Various modulation andprocessing techniques available to those skilled in the art are used forsignal transmission between the base station and the mobile terminal.

With reference to FIG. 3, a mobile terminal 16 configured according toone embodiment of the present invention is illustrated. Similarly to thebase station 14, the mobile terminal 16 will include a control system32, a baseband processor 34, transmit circuitry 36, receive circuitry38, multiple antennas 40, and user interface circuitry 42. The receivecircuitry 38 receives radio frequency signals bearing information fromone or more base stations 14. Preferably, a low noise amplifier and afilter (not shown) cooperate to amplify and remove broadbandinterference from the signal for processing. Downconversion anddigitization circuitry (not shown) will then downconvert the filtered,received signal to an intermediate or baseband frequency signal, whichis then digitized into one or more digital streams.

The baseband processor 34 processes the digitized received signal toextract the information or data bits conveyed in the received signal.This processing typically comprises demodulation, decoding, and errorcorrection operations. The baseband processor 34 is generallyimplemented in one or more digital signal processors (DSPs) andapplication specific integrated circuits (ASICs).

For transmission, the baseband processor 34 receives digitized data,which may represent voice, data, or control information, from thecontrol system 32, which it encodes for transmission. The encoded datais output to the transmit circuitry 36, where it is used by a modulatorto modulate a carrier signal that is at a desired transmit frequency orfrequencies. A power amplifier (not shown) will amplify the modulatedcarrier signal to a level appropriate for transmission, and deliver themodulated carrier signal to the antennas 40 through a matching network(not shown). Various modulation and processing techniques available tothose skilled in the art are used for signal transmission between themobile terminal and the base station.

In OFDM modulation, the transmission band is divided into multiple,orthogonal carrier waves. Each carrier wave is modulated according tothe digital data to be transmitted. Because OFDM divides thetransmission band into multiple carriers, the bandwidth per carrierdecreases and the modulation time per carrier increases. Since themultiple carriers are transmitted in parallel, the transmission rate forthe digital data, or symbols, on any given carrier is lower than when asingle carrier is used.

OFDM modulation utilizes the performance of an Inverse Fast FourierTransform (IFFT) on the information to be transmitted. For demodulation,the performance of a Fast Fourier Transform (FFT) on the received signalrecovers the transmitted information. In practice, the IFFT and FFT areprovided by digital signal processing carrying out an Inverse DiscreteFourier Transform (IDFT) and Discrete Fourier Transform (DFT),respectively. Accordingly, the characterizing feature of OFDM modulationis that orthogonal carrier waves are generated for multiple bands withina transmission channel. The modulated signals are digital signals havinga relatively low transmission rate and capable of staying within theirrespective bands. The individual carrier waves are not modulateddirectly by the digital signals. Instead, all carrier waves aremodulated at once by IFFT processing.

In operation, OFDM is preferably used for at least down-linktransmission from the base stations 14 to the mobile terminals 16. Eachbase station 14 is equipped with “n” transmit antennas 28, and eachmobile terminal 16 is equipped with “m” receive antennas 40. Notably,the respective antennas can be used for reception and transmission usingappropriate duplexers or switches and are so labeled only for clarity.

With reference to FIG. 4, a logical OFDM transmission architecture willbe described. Initially, the base station controller 10 will send datato be transmitted to various mobile terminals 16 to the base station 14.The base station 14 may use the channel quality indicators (CQIs)associated with the mobile terminals to schedule the data fortransmission as well as select appropriate coding and modulation fortransmitting the scheduled data. The CQIs may be directly from themobile terminals 16 or determined at the base station 14 based oninformation provided by the mobile terminals 16. In either case, the CQIfor each mobile terminal 16 is a function of the degree to which thechannel amplitude (or response) varies across the OFDM frequency band.

Scheduled data 44, which is a stream of bits, is scrambled in a mannerreducing the peak-to-average power ratio associated with the data usingdata scrambling logic 46. A cyclic redundancy check (CRC) for thescrambled data is determined and appended to the scrambled data usingCRC adding logic 48. Next, channel coding is performed using channelencoder logic 50 to effectively add redundancy to the data to facilitaterecovery and error correction at the mobile terminal 16. Again, thechannel coding for a particular mobile terminal 16 is based on the CQI.In some implementations, the channel encoder logic 50 uses known Turboencoding techniques. The encoded data is then processed by rate matchinglogic 52 to compensate for the data expansion associated with encoding.

Bit interleaver logic 54 systematically reorders the bits in the encodeddata to minimize the loss of consecutive data bits. The resultant databits are systematically mapped into corresponding symbols depending onthe chosen baseband modulation by mapping logic 56. Preferably,Quadrature Amplitude Modulation (QAM) or Quadrature Phase Shift Key(QPSK) modulation is used. The degree of modulation is preferably chosenbased on the CQI for the particular mobile terminal. The symbols may besystematically reordered to further bolster the immunity of thetransmitted signal to periodic data loss caused by frequency selectivefading using symbol interleaver logic 58.

At this point, groups of bits have been mapped into symbols representinglocations in an amplitude and phase constellation. When spatialdiversity is desired, blocks of symbols are then processed by space-timeblock code (STC) encoder logic 60, which modifies the symbols in afashion making the transmitted signals more resistant to interferenceand more readily decoded at a mobile terminal 16. The STC encoder logic60 will process the incoming symbols and provide “n” outputscorresponding to the number of transmit antennas 28 for the base station14. The control system 20 and/or baseband processor 22 as describedabove with respect to FIG. 2 will provide a mapping control signal tocontrol STC encoding. At this point, assume the symbols for the “n”outputs are representative of the data to be transmitted and capable ofbeing recovered by the mobile terminal 16.

For the present example, assume the base station 14 has two antennas 28(n=2) and the STC encoder logic 60 provides two output streams ofsymbols. Accordingly, each of the symbol streams output by the STCencoder logic 60 is sent to corresponding IFFT processor 62, illustratedseparately for ease of understanding. Those skilled in the art willrecognize that one or more processors may be used to provide suchdigital signal processing, alone or in combination with other processingdescribed herein. The IFFT processors 62 will preferably operate on therespective symbols to provide an inverse Fourier Transform. The outputof the IFFT processors 62 provides symbols in the time domain. The timedomain symbols are grouped into frames, which are associated with aprefix by prefix insertion logic 64. Each of the resultant signals isup-converted in the digital domain to an intermediate frequency andconverted to an analog signal via the corresponding digitalup-conversion (DUC) and digital-to-analog (D/A) conversion circuitry 66.The resultant (analog) signals are then simultaneously modulated at thedesired RF frequency, amplified, and transmitted via the RF circuitry 68and antennas 28. Notably, pilot signals known by the intended mobileterminal 16 are scattered among the sub-carriers. The mobile terminal16, which is discussed in detail below, will use the pilot signals forchannel estimation.

Reference is now made to FIG. 5 to illustrate reception of thetransmitted signals by a mobile terminal 16. Upon arrival of thetransmitted signals at each of the antennas 40 of the mobile terminal16, the respective signals are demodulated and amplified bycorresponding RF circuitry 70. For the sake of conciseness and clarity,only one of the two receive paths is described and illustrated indetail. Analog-to-digital (A/D) converter and down-conversion circuitry72 digitizes and downconverts the analog signal for digital processing.The resultant digitized signal may be used by automatic gain controlcircuitry (AGC) 74 to control the gain of the amplifiers in the RFcircuitry 70 based on the received signal level.

Initially, the digitized signal is provided to synchronization logic 76,which includes coarse synchronization logic 78, which buffers severalOFDM symbols and calculates an auto-correlation between the twosuccessive OFDM symbols. A resultant time index corresponding to themaximum of the correlation result determines a fine synchronizationsearch window, which is used by fine synchronization logic 80 todetermine a precise framing starting position based on the headers. Theoutput of the fine synchronization logic 80 facilitates frameacquisition by frame alignment logic 84. Proper framing alignment isimportant so that subsequent FFT processing provides an accurateconversion from the time domain to the frequency domain. The finesynchronization algorithm is based on the correlation between thereceived pilot signals carried by the headers and a local copy of theknown pilot data. Once frame alignment acquisition occurs, the prefix ofthe OFDM symbol is removed with prefix removal logic 86 and resultantsamples are sent to frequency offset correction logic 88, whichcompensates for the system frequency offset caused by the unmatchedlocal oscillators in the transmitter and the receiver. Preferably, thesynchronization logic 76 includes frequency offset and clock estimationlogic 82, which is based on the headers to help estimate such effects onthe transmitted signal and provide those estimations to the correctionlogic 88 to properly process OFDM symbols.

At this point, the OFDM symbols in the time domain are ready forconversion to the frequency domain using FFT processing logic 90. Theresults are frequency domain symbols, which are sent to processing logic92. The processing logic 92 extracts the scattered pilot signal usingscattered pilot extraction logic 94, determines a channel estimate basedon the extracted pilot signal using channel estimation logic 96, andprovides channel responses for all sub-carriers using channelreconstruction logic 98. In order to determine a channel response foreach of the sub-carriers, the pilot signal is essentially multiple pilotsymbols that are scattered among the data symbols throughout the OFDMsub-carriers in a known pattern in both time and frequency. Examples ofscattering of pilot symbols among available sub-carriers over a giventime and frequency plot in an OFDM environment are found in PCT PatentApplication No. PCT/CA2005/000387 filed Mar. 15, 2005 assigned to thesame assignee of the present application. Continuing with FIG. 5, theprocessing logic compares the received pilot symbols with the pilotsymbols that are expected in certain sub-carriers at certain times todetermine a channel response for the sub-carriers in which pilot symbolswere transmitted. The results are interpolated to estimate a channelresponse for most, if not all, of the remaining sub-carriers for whichpilot symbols were not provided. The actual and interpolated channelresponses are used to estimate an overall channel response, whichincludes the channel responses for most, if not all, of the sub-carriersin the OFDM channel.

The frequency domain symbols and channel reconstruction information,which are derived from the channel responses for each receive path areprovided to an STC decoder 100, which provides STC decoding on bothreceived paths to recover the transmitted symbols. The channelreconstruction information provides equalization information to the STCdecoder 100 sufficient to remove the effects of the transmission channelwhen processing the respective frequency domain symbols

The recovered symbols are placed back in order using symbolde-interleaver logic 102, which corresponds to the symbol interleaverlogic 58 of the transmitter. The de-interleaved symbols are thendemodulated or de-mapped to a corresponding bitstream using de-mappinglogic 104. The bits are then de-interleaved using bit de-interleaverlogic 106, which corresponds to the bit interleaver logic 54 of thetransmitter architecture. The de-interleaved bits are then processed byrate de-matching logic 108 and presented to channel decoder logic 110 torecover the initially scrambled data and the CRC checksum. Accordingly,CRC logic 112 removes the CRC checksum, checks the scrambled data intraditional fashion, and provides it to the de-scrambling logic 114 forde-scrambling using the known base station de-scrambling code to recoverthe originally transmitted data 116.

In parallel to recovering the data 116, a CQI, or at least informationsufficient to create a CQI at the base station 14, is determined andtransmitted to the base station 14. As noted above, the CQI may be afunction of the carrier-to-interference ratio (CR), as well as thedegree to which the channel response varies across the varioussub-carriers in the OFDM frequency band. The channel gain for eachsub-carrier in the OFDM frequency band being used to transmitinformation is compared relative to one another to determine the degreeto which the channel gain varies across the OFDM frequency band.Although numerous techniques are available to measure the degree ofvariation, one technique is to calculate the standard deviation of thechannel gain for each sub-carrier throughout the OFDM frequency bandbeing used to transmit data.

FIGS. 1 to 5 each provide a specific example of a communication systemor elements of a communication system that could be used to implementembodiments of the invention. It is to be understood that embodiments ofthe invention can be implemented with communications systems havingarchitectures that are different than the specific example, but thatoperate in a manner consistent with the implementation of theembodiments as described herein.

A MAC (media access control) layer is used to enable features in thephysical (PHY) layer in an OFDM air interface framework. Frames are aformat used to transmit data over the air interface between basestations (BS) and wireless terminals. A wireless terminal, as referredto hereafter, is any OFDM capable wireless device and may be fixedlocation, nomadic or mobile, for example a cellular telephone, computerwith a wireless modem, or PDA. The frame also includes informationelements (IE) to provide a structure within the frame for defining wheredown-link and up-link transmissions are located within the frame.

FIG. 6 shows a schematic diagram of an example frame used in conjunctionwith embodiments of the invention. Details are shown for a framelabelled “Frame N”, generally indicated at 205, which is preceded by“Frame N−1” and followed by “Frame N+1”, all forming part of an ongoingsequence of frames. The frame has a two dimensional appearance which isrepresented in terms of a rows and columns. The rows are designated bylogical subchannel numbers L, L+1, . . . L+15 and the columns aredesignated by OFDM symbol numbers M, M+1, . . . M+15. Logicalsubchannels are designated groupings of active subcarriers. Activesubcarriers are any one of data subcarriers for data transmission, pilotsubcarriers for synchronization, or subcarriers that do not involvedirect transmission, but are used as transition guards between parts ofthe frame. In the frame N of FIG. 6, a preamble 210 is included in afirst OFDM symbol M. A second OFDM symbol M+1 and a third OFDM symbolM+2 include both a down-link (DL) mapping component 212 (more commonlyreferred as a DL MAP message in the IEEE 802.16 standard) including oneor more information elements 213 and an up-link (UL) mapping component214 (more commonly referred to as a UL MAP message in the IEEE 802.16standard) including one or more information elements 215. Otherbroadcast messages (not shown) may be included as well. Subsequent OFDMsymbols M+3 through M+9 contain a DL subframe 217. The DL subframe 217contains DL information allocated to regions 216 of the DL subframe 217to be transmitted to one or more wireless terminals by the base station.Following the DL subframe 217 is a transmit/receive/transition guard(TTG) 218, shown during OFDM symbol period M+10. After the TTG 218 is aUL subframe 219 containing UL information allocated to designatedregions 224 of the UL subframe to be transmitted back to the basestation by the one or more wireless terminals. The UL subframe 219 alsoincludes fast feedback channels 222 that are used to allow the mobileterminal to report information to the base station. For example a fastfeedback channel 222 can be designated as a channel to indicate the airinterface channel quality between the base station and the mobileterminal. Following the UL subframe 219 is a receive/transmit transitionguard (RTG) 220. Frames N−1 and N+1 have a similar composition.

Regions 216 of the DL subframe 217 contain MAC protocol data units(PDU). Regions 224 of the UL subframe 219 also contain MAC PDUs. MACPDUs are known to include some or all of the following: a MAC header,MAC subheaders and a MAC payload.

The data frame of FIG. 6 is an example of a time division duplex (TDD)data frame. It is to be understood that embodiments of the invention arealso applicable to frequency division duplex (FDD) operation.

The illustrated frame structure is a specific example. The preamble,mapping components, DL subframe and UL subframe may be implemented usingan implementation specific number of OFDM symbols, with implementationspecific guard bands. The number and definition of OFDM subchannels isalso an implementation detail. The layout sequence of the various fieldscan also be varied.

Each region 216 of the DL subframe 217 and/or each region 224 of the ULsubframe 219 may contain multiple packets of MAC PDU information. Inorder to facilitate down-link data transmission by a base station to awireless terminal, some feedback information, such as C/I(carrier-to-interference) measurements, and/or wireless terminalindications, such as MIMO (multiple input multiple output)/permutationmodes, are sent from the wireless terminal.

An automatic repeat request (ARQ) scheme involves, in a communicationbetween two devices, a device receiving a transmission from atransmitting device automatically sending an acknowledgement (ACK) of areceived and decoded message or a negative acknowledgement (NAK) of amessage that is not received or not able to be decoded. The NAKgenerally acts as a request for re-transmission of the originallytransmitted transmission.

In conventional ARQ schemes transmission errors are generally determinedat the receiver by an error detection code. In an enhancement to ARQ,known as hybrid automatic repeat request (H-ARQ), error detection of theARQ scheme is combined with an error correcting to create a scheme toincrease the probability of successful transmission.

The embodiments of the invention described below provide methods forimplementing OFDM H-ARQ communications between a base station and one ormore wireless terminals using an existing DL MAP structure in the IEEE802.16 standard. The DL MAP structure has both the DL mapping componentregion and the UL mapping component region as described above withregard to FIG. 6.

More generally, it is to be understood that the methods can be appliedto other types of H-ARQ based communication in addition to thosesupported in the IEEE 802.16 standard.

Three different types of H-ARQ enabled communications being implementedwith the methods described herein include incremental redundancy (IR)based H-ARQ, Chase based H-ARQ, and STC (space-timing code combining)based H-ARQ. With respect to IR based H-ARQ and Chase based H-ARQ,methods and systems are described herein that are appropriate for eitherMIMO or non-MIMO capable wireless terminals. With respect to STC basedH-ARQ, methods and systems are provided that are appropriate for MIMOcapable wireless terminals.

In H-ARQ schemes a MAC layer PDU is transferred to the PHY layer and aPHY layer PDU is created and transmitted to a receiver. At the receivingdevice, the received PHY layer PDU is transferred to the MAC layer whereit is decoded.

In some embodiments, transmission using IR based H-ARQ involves a basestation sending encoded information to a wireless terminal on a channelfor H-ARQ transmissions with a specific identification (H-ARQ channelID). If the wireless terminal does not properly receive and decode theencoded information, the wireless terminal sends a NAK to the basestation requesting retransmission on the H-ARQ transmission channel withthe same ID as the original encoded information. The base station thensends additional encoded information to the wireless terminal on thesame H-ARQ transmission channel to aid the wireless terminal in decodingthe original encoded information. Typically, the additional encodedinformation is select parity bits. If the base station receives afurther NAK from the wireless terminal the base station sends furtheradditional encoded information to the wireless terminal on the sameH-ARQ transmission channel. The further additional encoded informationmay be a different selection of parity bits from the first selection ofparity bits. This process continues until the wireless terminal properlyreceives and decodes the original encoded information or until apre-determined number of additional encoded information packets aresent. The additional selections of encoded information do not typicallyinclude all the same data of the first encoded information. This allowsfor a more efficient use of transmission bandwidth, as instead ofre-transmitting an entire message to the wireless terminal multipletimes, the base station may subsequently send smaller selections ofencoded information to aid in properly decoding the original encodedinformation.

For example, encoded information may be a PHY layer PDU including a MACPDU or a portion of a MAC PDU along with redundancy or parity bits thatare used to aid in error correction of the encoded information, whenerrors are detected subsequent to transmission. In some embodiments, thePHY layer PDU is divided into more than one sub-packet. A firstsub-packet contains all of or the portion of the MAC PDU and also mayinclude some of the parity bits. The remaining sub-packets include theremainder the parity bits. The parity bits in the other sub-packets mayeach contain a random selection of the remaining parity bits from thesequential order of parity bits that make up the PHY PDU. A typicalnumber of sub-packets may be four. However, the number of sub-packetsmay be greater than or less than four depending on the desiredimplementation.

In some embodiments, multiple H-ARQ channels are used for transmissionof PHY layer PDUs as transmission of a single PHY layer PDU occurs overmore than one transmission frame due to the temporal nature oftransmission of information between the base station and receiver. Forexample in the IR based H-ARQ scheme, the base station transmits thefirst sub-packet in a first frame, if the first sub-packet is notsuccessfully received the receiver must send a NAK back in a subsequentframe. After the NAK is received at the base station, another frame isused to send the second sub-packet. As this process may occur formultiple simultaneous PHY layer PDUs transmitted to one or more than onereceiver, the use of multiple H-ARQ channels is advantageous.

As an example, a first encoded PHY layer PDU sub-packet is transmittedfrom the base station to the wireless terminal, which includes the MACPDU or portion thereof and select parity bits. Encoded PHY layer PDUsub-packets and the corresponding NAKs are transmitted on a channelidentified for H-ARQ transmission over the connections establishedbetween the base station and the one or more wireless terminals. If thebase station receives a NAK from the wireless terminal, the base stationthen sends a second PHY layer PDU sub-packet to the wireless terminalincluding different select parity bits than the parity bits sent withthe first PHY layer PDU sub-packet. If the base station receives afurther NAK from the wireless terminal the base station sends a thirdPHY layer PDU sub-packet to the wireless terminal of other select paritybits that have not yet been sent. This process continues until thewireless terminal properly receives and decodes the MAC PDU or portionthereof or when all the parity bits in the maximum number of sub-packetsare eventually sent.

An example of IR based H-ARQ will now be described with respect to FIG.7. FIG. 7 is a signaling diagram between a base station 710 and awireless terminal 720 in which multiple H-ARQ channels are being used totransmit H-ARQ transmission in a DL direction in multiple DL regions ofthe frame. At 725, a first PHY layer PDU sub-packet with a sub-packetidentification (SPID) equal to 1 is sent on a first H-ARQ transmissionchannel (ACID=1) by the base station 710 to the wireless terminal 720.At 730, a first PHY layer PDU sub-packet with a SPID equal to 1 is senton a second H-ARQ channel (ACID=2) by the base station 710 to thewireless terminal 720. At 735, a first PHY layer PDU sub-packet with aSPID equal to 1 is sent on a third H-ARQ channel (ACID=3) by the basestation 710 to the wireless terminal 720. At 740, a NAK is sent from thewireless terminal 720 to the base station 710 on ACID=1. In response tothe received NAK on ACID=1, at 745 a second PHY layer PDU sub-packet istransmitted on ACID=1 with a SPID equal to 2 from the base station 710to the wireless terminal 720. At 750, a NAK is sent from the wirelessterminal 720 to the base station 710 on ACID=3. At 755, a first PHYlayer PDU sub-packet with a SPID equal to 1 is sent on a fourth H-ARQchannel (ACID=4) by the base station 710 to the wireless terminal 720.In response to the received NAK on ACID=3, at 760 a second PHY layer PDUsub-packet is transmitted on ACID=3 with a SPID equal to 2 from the basestation 710 to the wireless terminal 720. At 765, a new first PHY layerPDU sub-packet is transmitted on ACID=2 with a SPID equal to 1 from thebase station 710 to the wireless terminal 720. This process continuesuntil all PHY layer PDU sub-packets sent by the base station 710 arereceived by the wireless terminal 720. This example is directed totransmission of data or messages in the DL direction, but a similarprocess occurs in the UL direction.

In some embodiments, transmission using Chase based H-ARQ involves thebase station sending encoded information on a channel for H-ARQtransmissions with a H-ARQ channel ID and then re-sending the entireencoded information each time a NAK is received from the wirelessterminal indicating that the wireless terminal was not able to properlyreceive and/or decode the first encoded information. Chase based H-ARQis considered to be less efficient than IR based H-ARQ as Chase basedH-ARQ resends the entire encoded information each time a NAK isreceived, whereas IR based H-ARQ sends the encoded information and someparity bits in the first transmission and only select parity bits insubsequent transmissions when a NAK is received.

An example of Chase based H-ARQ will now be described with respect toFIG. 8. FIG. 8 is a signaling diagram between a base station 810 and awireless terminal 820. At 825, a first PHY layer PDU packet istransmitted on a first H-ARQ channel (ACID=1) a first time (Tx_Count=1)by the base station 810 to the wireless terminal 820. At 830, a firstPHY layer PDU packet is transmitted on a second H-ARQ channel (ACID=2) afirst time (Tx_Count=1) by the base station 810 to the wireless terminal820. At 835, a NAK is sent from the wireless terminal 820 to the basestation 810 on ACID=2. At 840, a first PHY layer PDU packet istransmitted on a third H-ARQ channel (ACID=3) a first time (Tx_Count=1)by the base station 810 to the wireless terminal 820. In response to thereceived NAK on ACID=2, at 845 the first PHY layer PDU packet isre-transmitted (Tx_Count=2) on ACID=2 by the base station 810 to thewireless terminal 820. At 850, a new first PHY layer PDU packet is senton ACID=1 a first time (Tx_Count=1) by the base station 810 to thewireless terminal 820. This process continues until all PHY layer PDUpackets sent by the base station 810 are received by the wirelessterminal 820. As with the IR based H-ARQ example above, this example isdirected to transmission of data or messages in the DL direction, but asimilar process occurs in the UL direction.

It is to be understood that the above examples take place over thecourse of multiple transmit frames as a NAK or re-transmission can onlybe sent in subsequent frames to an originally transmitted H-ARQtransmission. It is also to be understood that the same concept shownfor the base station transmitting to the mobile terminal applies to thebase station transmitting to more than one wireless terminal indifferent regions of the frame.

Transmission using STC based H-ARQ is similar to Chase based H-ARQ inthat STC based H-ARQ involves the base station sending first encodedinformation and then re-sending the entire first encoded informationeach time a NAK is received from the wireless terminal. Using MIMO mode,it is possible to exploit spatial diversity to enhance H-ARQ performancethrough a particular transmission arrangement of the encodedinformation. In some embodiments, for STC based H-ARQ the base stationindicates a transmission count to provide the receiving device with anindication of how many times the encoded information has beentransmitted. In some embodiments of the invention, the transmittingdevice will send the receiving device location information forassignment of a region in the DL sub-frame of the data frame or the slotof the UL sub-frame of the data frame for the first encoded informationonly. Subsequent transmissions of encoded information are transmitted inthe same assigned region or slot, so the receiving device knows where tolocate the subsequent transmissions.

In MIMO mode transmission, if a received first packet including encodedinformation is in error, then a re-transmission is requested and thetransmitter can use the same STC format as was originally sent tore-send the packet. In this case, the packet can be re-transmitted usingthe same FEC encoded information or can be re-transmitted usingdifferent FEC redundancy, the re-transmitted packet and erroneous firstpacket can be combined in soft symbol form or can be decoded with there-transmitted packet and erroneous first packet as a code combining.

A H-ARQ channel described above in the H-ARQ schemes for H-ARQtransmissions, and identified by a H-ARQ channel ID, in someembodiments, is one of many channels for H-ARQ transmissions assigned toa particular connection, identified by a connection identification (CID)between a base station and a wireless terminal.

In some embodiments, the H-ARQ schemes involve transmissions in the DLand UL directions where a transmitting device, that is the base stationand/or the wireless terminal, maintains a queue of transmissions to besent to a receiving device over consecutive data frames of the typedescribed above. The base station provides an indication to both thebase station itself and one or more wireless terminals of locations oftransmission resources in the DL and UL subframes of the frame where theH-ARQ transmissions are to be transmitted. The base station and the oneor more wireless terminals can then transmit the transmissions in theallocated resources according to the order of transmissions in thequeue.

When the transmitting device receives a NAK from the receiving device,the transmitting device then schedules a re-transmission of thenon-received transmission at an appropriate location within the queuesuch that a continuous flow of transmissions occurs on all H-ARQchannels and transmissions of no one H-ARQ channel falls behind in atransmission sequence. While transmissions of encoded information thatarrive out of sequence are not a difficult problem to overcome due tothe specific identification of each transmission of encoded information,it may become problematic if some of the packets become unmanageably outof sequence. The following methods for DL and UL direction H-ARQtransmissions involve how the base station assigns transmissionresources from the base station to the wireless terminal or vice versabased on scheduling needs of the different H-ARQ schemes.

H-ARQ Transmissions in the Down-Link Direction

Embodiments of the invention directed to a non-MIMO IR based H-ARQscheme will now be described based on FIG. 9. The base station transmitsan indication of a total number of assignments or particular resourceallocations to be allocated to all the wireless terminal currently inthe range of the base station at step 1510. Then for each assignment thebase station indicates the location in the frame where the encodedinformation being sent using the IR based H-ARQ scheme is to betransmitted in the frame at step 1520. This may include such positionalinformation as OFDM symbol offset and subchannel offset from a startingpoint within the frame and information indicating size of the particularallocated assignment such as a number of OFDM symbols and a number ofsubchannels the H-ARQ transmission is to occupy. The base station mayalso send other information to the wireless terminal for eachassignment, for example information relating to signal power of thetransmission. The base station also sends an indication to the wirelessterminal to identify if the H-ARQ transmission sent by the base stationis repetitively coded at step 1530. For example, to ensure a more robusttransmission the transmitted information may first be encoded multipletimes for a single transmission. In some embodiments, the repetitioncoding indication involves the base station sending an indication of aquantity or number of times that the pre-coded data or message isrepetitively encoded. This indication may be that the pre-coded data isrepetitively coded 2, 4 or 6 times or possibly there are no repetitionsand the information is only encoded once. The base station sends thewireless terminal an identification of a H-ARQ channel upon which theencoded information for the particular assignment is transmitted at step1540. As described above each connection between the base station andthe one or more wireless terminal can have more than one H-ARQ channel.The base station also sends the wireless terminal an indication of whena new packet of encoded information in a packet transmission sequence isbeing sent for the particular assignment at step 1550. In someembodiments for example, this indication may simply entail a single bitthat is alternated between 0 and 1 each time a new packet istransmitted. For each assignment the base station also sends anidentification of the particular sub-packet that is being sent by thebase station at step 1560, for example the first, second- or thirdsub-packet as generally described above. In some embodiments for eachassignment the base station also sends the wireless terminal a PHYprofile at step 1570, in the form of a down-link interval usage code(DIUC) and connection identification (CID). There may also be additionalpadding bits in the transmission from the base station to the wirelessterminal to provide an integer number of bytes in the base stationtransmission.

The combined use of the H-ARQ channel ID, indication of when a newpacket is transmitted and sub-packet ID is one example of howtransmission and re-transmission of packets can be identified. It is tobe understood that there may be alternative identification methods withfewer or more variables for proper identification of the packets beingtransmitted. For example, an indication of a first sub-packet may besufficient as an indication of when a new packet is being transmittedand thus no specific indication of when a new packet is transmitted isused.

The above is an example for an IR based H-ARQ scheme. It is to beconsidered to be within the scope of the invention that not all of theparticular indications and identifications are sent by the base station.In some embodiments, not all of the described indications oridentification may be sent, or in some embodiments additionalinformation may be sent by the base station to enhance the IR-basedH-ARQ. The same can be said of all DL and UL direction H-ARQ schemesdescribed herein.

Embodiments of the invention directed to a MIMO IR based H-ARQ schemewill now be described based on FIG. 10. Utilizing MIMO IR based H-ARQincludes many of the aspects utilized in non-MIMO IR based H-ARQ withthe addition of the base station identifying for each assignment aparticular matrix format used for transmitting the H-ARQ transmission inan appropriate MIMO format at step 1640. The base station sends thewireless terminal an indication of the total number of coding streams orlayers utilized by the transmitter for transmitting the H-ARQtransmission according to the selected MIMO matrix format at step 1650.For each coding stream or layer the base station sends the wirelessterminal a PHY profile (step 1695) in the form of a DIUC and CID, anindication of the layer index (step 1660), an indication of the H-ARQchannel identification (step 1670), an indication of the packet sequencenumber (step 1680) and an indication of the sub-packet ID (step 1690).There may also be additional padding bits in the transmission to providean integer number of bytes in the base station transmission.

Embodiments of the invention directed to a non-MIMO Chase based H-ARQscheme will now be described based on FIG. 11. When utilizing non-MIMOChase based H-ARQ, the base station sends to the wireless terminal anindication of a number of assignments to be performed at step 1710, thenfor each assignment the base station indicates to the wireless terminalthe location in the frame of where the H-ARQ transmission is to betransmitted in the frame at 1720. As with the IR based H-ARQ schemesthis may include such positional information as an OFDM symbol offsetand subchannel offset from the start of the frame and information thatindicates the size of the particular allocated assignment such as thenumber of OFDM symbols and number of subchannels. The base station mayalso send other information to the wireless terminal for eachassignment, such as signal power information. The base station may senda repetition coding indication at step 1730 of a type described above.The base station sends the wireless terminal an identification of thechannel used for the H-ARQ transmission for the particular assignment atstep 1740. The base station also sends the wireless terminal anindication of how many times the transmission has been sent at step1750, also know as the transmission count, for example if it is thefirst, second, third or additional transmission of the entire packet. Insome embodiments, for each assignment the base station also sends thewireless terminal a PHY profile at step 1760, in the form of a DIUC andCID. There may also be additional padding bits in the transmission toprovide an integer number of bytes in the base station transmission.

Embodiments of the invention directed to a MIMO Chase based H-ARQ schemewill now be described based on FIG. 12. Utilizing MIMO Chase based H-ARQincludes many of the aspects utilized in non-MIMO Chase based H-ARQ withthe addition of the base station identifying for each assignment aparticular matrix format used for transmitting the H-ARQ transmission inan appropriate MIMO format in step 1840. The base station sends thewireless terminal an indication of a total number of coding streams orlayers utilized by the transmitter for transmitting the H-ARQtransmission according to the selected MIMO matrix format at step 1850.For each of the layers the base station sends the wireless terminal aPHY profile, in the form of a DIUC and CID (step 1890), an indication ofthe layer index (step 1860), an indication of the H-ARQ channelidentification (step 1870), and an indication of the transmission count(step 1380). There may also be additional padding bits in thetransmission to provide an integer number of bytes in the base stationtransmission.

Embodiments of the invention directed to a STC based H-ARQ scheme willnow be described based on FIG. 13. The STC based H-ARQ communicationsare used with MIMO enabled communications systems using STC mode. Whenutilizing STC based H-ARQ, the base station sends to the wirelessterminal an indication of a total number of assignments to be performedat step 1910, then for each assignment the base station sends atransmission count at step 1920, which is an indication of how manytimes the transmission has be sent. When the transmission countindicates that it is the first transmission being sent, the base stationsends to the wireless terminal an indication of the location in theframe of where the H-ARQ transmission is to be transmitted at step 1930.This may include such positional information as an OFDM symbol offsetand subchannel offset from the start of the frame and information thatindicates the size of the particular allocated assignment such as thenumber of OFDM symbols and number of subchannels. The base station mayalso send other information to the wireless terminal for eachassignment, such as transmission signal power information. The basestation may send a repetition coding indication at step 1940 asdescribed above pertaining to IR and Chase based H-ARQ. The base stationalso sends the wireless terminal an identification of a H-ARQ channel atstep 1950 upon which the encoded information for the particularassignment is transmitted. There may also be additional padding bits inthe transmission to provide an integer number of bytes in the basestation transmission. When the transmission count indicates that it isnot the first transmission as shown at step 1960 the wireless terminalknows where to locate the H-ARQ re-transmission based on the positionalinformation previously received for the first transmission so thepositional information is not re-transmitted. In some embodiments foreach assignment the base station also sends the wireless terminal a PHYprofile at step 1970, in the form of a DIUC and CID.

In some embodiments of the invention, the base station sends thewireless terminal the information described above for MIMO or non-MIMOIR based H-ARQ and/or MIMO or non-MIMO Chase based H-ARQ and/or STCbased H-ARQ in the form of an information element (IE) that could betransmitted by the base station in a portion of a data frame such as thedown-link mapping component 212 of the data frame of FIG. 6. In someembodiments of MIMO or non-MIMO IR based H-ARQ and/or MIMO or non-MIMOChase based H-ARQ as well as STC based H-ARQ, the base station may alsosend the wireless terminal an indication of the type of IE that the basestation is sending, namely MIMO or non-MIMO IR based H-ARQ and/or MIMOor non-MIMO Chase based H-ARQ and/or STC based H-ARQ. This indication ofthe type of IE may be in the form of an Extended DIUC.

Tables 1-5 below are particular examples of formats for such IE.

IR_H-ARQ MAP IE

The following is an example of a format of a down-link IE that may beused in a down-link mapping component such as 212 of FIG. 6. This IE istransmitted by a base station to one or multiple wireless terminals thatare running H-ARQ enabled connections and using IR mode.

TABLE 1 IR_H-ARQ MAP IE Size Syntax (bits) Note IR_H-ARQ_IE( ) ExtendedDIUC 4 IR_H-ARQ = 0x09 Length 4 Num_Assignments 2 For(1=0;i<Num_Assignments;i+ +) { DIUC 4 CID 16 OFDMA Symbol offset 8Subchannel offset 6 Boosting 3 No. of OFDMA symbols 8 No. of subchannels6 Repetition coding 2 indication ACID 3 H-ARQ channel ID Packet_SN 1Packet sequence number. When changed, it means a new packet is beentransmitted SPID 2 Sub-packet ID } Padding bits Variable Padding bits toalign boundary of byte }

The following is a brief description of each of the fields in Table 1.Many of the fields have been previously described in the generaloperation of the H-ARQ transmission.

An Extended DIUC is another grouping of code values. The “Extended DIUC”field is used to associate a code value to identify a particular type ofIE. For example, the “IR_H-ARQ” IE in Table 1 has an “Extended DIUC”=09.Other IE described below may have different respective Extended DIUCvalues.

The “Length” field indicates the size of the IE. Therefore, if areceiver identifies that that the particular IE is not relevant to thereceiver, it can advance to the next IE in the frame to see if it isrelevant to the receiver, by advancing a value equal to the lengthfield. In some embodiments for example, the “Length” field is the lengthof the IE as a number of bytes.

The “Num_Assignments” field indicates the number of assignments orallocations being made in the down-link portion of the frame formessages or information being transmitted from the base station to oneor more wireless terminals.

The “For” loop is provided to supply description information for eachassignment of the total number of assignments of the “Num_Assignments”field.

The “DIUC” field is set equal to a predefined value that indicates atype of transmission format, for example a coding scheme, used fortransmitting data or messages in each assignment of the total number ofassignments.

The “CID” field identifies a connection between a base station and aparticular wireless terminal in each assignment of the total number ofassignments.

The “OFDMA Symbol offset” and “Subchannel offset” fields indicate aninitial starting point in the frame for each assignment of the totalnumber of assignments. The “No. of OFDMA symbols” and “No. ofsubchannels” fields indicate how many of each symbols or subchannels,respectively are allotted to each assignment of the total number ofassignments from the initial OFDMA Symbol offset and Subchannel offsetstarting points. The “Boosting” field is an indication of relativetransmission signal power between pilot and data tones.

The “Repetition coding indication” field indicates a total number oftimes that the pre-coded version of the data or message to be sent ineach assignment of the total number of assignments is encoded.

The “ACID”, “Packet_SN”, and “SPID” fields are used in combination toidentify a particular component of data or message being transmitted ineach assignment of the total number of assignments. The “ACID” fieldindicates the H-ARQ channel used to transmit the data or message. The“Packet_SN” filed indicates when a new packet is being transmitted andas described above may be a single bit that alternates each time a newbit is transmitted. The “SPID” field indicates a particular sub-packetidentification so that the wireless terminal will know how thesub-packet is to be used in receiving and decoding the information, forexample if the sub-packet is the first sub-packet containing the encodeddata or a subsequent sub-packet containing information such as paritybits to aid in decoding the first sub-packet.

The values provided in Table 1 or subsequent tables below are mereexamples of code values that could be used for the various fields and itis to be understood that the code values assigned and the number of bitsused to represent the codes values could be varied according to adesired usage.

Chase_H-ARQ MAP IE

The following is an example of a format of a down-link IE that may beused in a down-link mapping component such as 212 of FIG. 6. This IE istransmitted by a base station to one or multiple wireless terminals thatare running H-ARQ enabled connections and using Chase mode.

TABLE 2 Chase_H-ARQ MAP IE Size Syntax (bits) Note Chase_H-ARQ_IE( )Extended DIUC 4 Length 4 Num_Assignments 2 For (i=0;i<Num_Assignments;i++) { DIUC 4 CID 16 OFDMA Symbol offset 8 Subchannel offset 6 Boosting3 No. of OFDMA 8 symbols No. of subchannels 6 Repetition coding 2indication ACID 3 H-ARQ channel ID Tx_Count 2 Transmission count: 00:first transmission 01: second transmission 10: third transmission 11:fourth transmission } Padding bits Variable Padding bits to alignboundary of byte }

The fields of the “Chase_H-ARQ MAP” IE are essentially the same as the“IR_H-ARQ MAP IE”, with the exception that the “Packet_SN” and “SPID”fields of the IR based IE are replaced with a “Tx_Count” field. The“Tx_Count” field indicates which particular transmission of encoded datais being transmitted in each assignment of the total number ofassignments. As described above, with Chase based H-ARQ the entiretransmission is re-transmitted each time a NAK is received. The“Tx_Count” field allows the wireless receiver to keep track of whichtransmission it is receiving.

MIMO_IR_H-ARQ MAP IE

The following is an example of a format of a down-link IE that may beused in a down-link mapping component such as 212 of FIG. 6. This IE istransmitted by a base station to one or multiple MIMO-capable wirelessterminals that are running H-ARQ enabled connections and using IR mode.

TABLE 3 MIMO_IR_H-ARQ MAP IE Size Syntax (bits) Note MIMO_IR_H-ARQ_IE( )Extended DIUC 4 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { OFDMA Symbol offset 8 Subchannel offset 6Boosting 3 No. of OFDMA symbols 8 No. of subchannels 6 Repetition coding2 indication Matrix_indicator 2 Num_Layer 2 For i=0;i<Num_Layers;i++) {CID 16 DIUC 4 Layer_index 2 ACID 3 H-ARQ channel ID Packet_SN 1 Packetsequence number. When changed, it means a new packet is been transmittedSPID 2 Sub-packet ID  } } Padding bits Variable Padding bits to alignboundary of byte }

The fields of the “MIMO_IR_H-ARQ MAP” IE are essentially the same asthose found in the “IR_H-ARQ MAP” IE except that a “Matrix_indicator”field indicates for each assignment of the total number of assignments atype of matrix that is used for transmitting data or messages in eachassignment. Also, for each assignment, a total number of layers orstreams of transmission for each assignment are indicated by the“Num_Layer” field. Subsequently, a second “For” loop is used forindicating to the wireless terminal information about each layer of thetotal number of layers. Specifically, the “CID” and “DIUC” fields servethe same purpose as the “IR_H-ARQ MAP” IE. In addition to the “ACID”,“Packet_SN”, and “SPID” fields in the “IR_H-ARQ MAP” IE, the“MIMO_IR_H-ARQ MAP” IE also has a “Layer_index” field indicating towhich layer of the total number of layers the “ACID”, “Packet_SN”, and“SPID” fields pertain.

MIMO_Chase_H-ARQ MAP IE

The following is an example of a format of a down-link IE that may beused in a down-link mapping component such as 212 of FIG. 6. This IE istransmitted by a base station to one or multiple MIMO-capable wirelessterminals that are running H-ARQ enabled connections and using Chasemode.

TABLE 4 MIMO_Chase_H-ARQ MAP IE Size Syntax (bits) Note MIMO_Chase_H-ARQ_IE( ) Extended DIUC 4 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { OFDMA Symbol offset 8 Subchannel offset 6Boosting 3 No. of OFDMA symbols 8 No. of subchannels 6 Repetition codingindication 2 Matrix_indicator 2 Num_Layer 2 For i=0;i<Num_Layers;i++) {CID 16 DIUC 4 Layer_index 2 ACID 3 H-ARQ channel ID Tx_Count 2Transmission count: 00: first transmission 01: second transmission 10:third transmission 11: fourth transmission } } Padding bits VariablePadding bits to align boundary of byte }

The fields of the “MIMO_Chase_H-ARQ MAP” IE are essentially the same asthose found in the “Chase_H-ARQ MAP” IE except that a “Matrix_indicator”field indicates for each assignment of the total number of assignments atype of matrix that is used for transmitting data or messages in eachassignment. Also, for each assignment, a total number of layers orstreams of transmission for each assignment are indicated by the“Num_Layer” field, similar to that of the “MIMO_IR_H-ARQ MAP” IE.Subsequently, a second “For” loop is used for indicating to the wirelessterminal information about each layer of the total number of layers.Specifically, the “CID” and “DIUC” fields serve the same purpose as the“IR_H-ARQ MAP” IE. In addition to the “Tx_Count” field in the“Chase_H-ARQ MAP” IE, the “MIMO_Chase_H-ARQ MAP” IE also has a“Layer_index” field indicating to which layer of the total number oflayers the “Tx_Count” field pertains.

STC_H-ARQ MAP IE

The following is an example of a format of a down-link IE that may beused in a down-link mapping component such as 212 of FIG. 6. This IE istransmitted by a base station to one or multiple MIMO-capable wirelessterminals that are running H-ARQ enabled connections and using STC mode.The re-transmission matrix used depends on a number of base stationtransmission antennas. Examples of re-transmission matrices used arefound in Section 8.4.8.9 of IEEE standard P802.16e/D9 (June 2005), whichis hereby incorporated in its entirety.

TABLE 5 STC_H-ARQ MAP IE Size Syntax (bits) Note STC_H-ARQ_IE( )Extended DIUC 4 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { DIUC 4 CID 16 Tx_Count 2 Transmissioncount: 00: first transmission 01: second transmission 10: thirdtransmission 11: fourth transmission If (Tx_Count == 00) { OFDMA Symboloffset 8 Subchannel offset 6 Boosting 3 No. of OFDMA symbols 8 No. ofsubchannels 6 Repetition coding 2 indication } ACID 3 H-ARQ channel ID }Padding bits Variable Padding bits to align boundary of byte }

The fields of the “STC_H-ARQ MAP” IE have many fields in common with the“IR_H-ARQ MAP” IE and the “Chase_H-ARQ MAP” IE.

After initiating a first “For” loop performed for each assignment of atotal number of assignments, in which “DUIC” and “CID” fields areprovided, a “Tx_Count” field is included in the IE which acts similar tothe same named field in the “Chase_H-ARQ MAP”. An “If” condition in theIE indicates the starting point, size of the assignment, boostinginformation and repetition coding information if the “If” condition istrue, that is for a first transmission.

An “ACID” field indicates the H-ARQ channel, similar to the other IR andChase IEs above for each assignment of the total number of assignments.

H-ARQ Transmissions in the Up-Link Direction

Embodiments of the invention directed to a non-MIMO IR based H-ARQscheme will now be described based on FIG. 14. The base station sends tothe wireless terminal an indication of a total number of assignments tobe performed at step 2010, then for each assignment the base stationindicates to the wireless terminal the duration of the assignment in theframe where the H-ARQ transmission is to be transmitted in the frame atstep 2020. The base station sends a repetition coding indication of atype described above for down-link IR based H-ARQ at step 2030. The basestation sends the wireless terminal an identification of a H-ARQ channelupon which the encoded information for the particular assignment istransmitted at step 2040. The base station also sends the wirelessterminal an indication of when a new packet in a packet transmissionsequence is being sent for the particular assignment at step 2050. Insome embodiments, for example this indication may simply entail a singlebit that is alternated between 0 and 1 each time a new packet istransmitted. For each assignment the base station also sends anidentification of the particular sub-packet that is being sent by thebase station at step 2060, for example the first, second or thirdsub-packet as described above for down-link base H-ARQ. In someembodiments, for each assignment the base station also sends thewireless terminal a PHY profile at step 2070, in the form of an up-linkinterval usage code (UIUC) and CID. There may also be additional paddingbits in the transmission to provide an integer number of bytes in thebase station transmission.

Embodiments of the invention directed to a MIMO IR based H-ARQ schemewill now be described based on FIG. 15. When utilizing MIMO IR basedH-ARQ, the base station sends to the wireless terminal an indication ofa total number of assignments to be performed at step 2110, then foreach assignment the base station indicates to the wireless terminal theduration of the assignment in the frame where the H-ARQ transmission isto be transmitted in the frame at step 2115. For each assignment thebase station sends an indication if the up-link signal is to come from adual antenna transmission capable wireless terminal or a collaborationof two single antenna spatial multiplexing (SM) capable wirelessterminals at step 2120. If a dual antenna transmission capable wirelessterminal is selected as indicated at step 2125, then the base stationsends an indication of whether MIMO communication is performed usingspace-time transmit diversity (STTD) or spatial multiplexing (SM) atstep 2126. Following this indication the base station sends a repetitioncoding indication at step 2127. The base station also sends the wirelessterminal an identification of a H-ARQ channel upon which the encodedinformation for the particular assignment is transmitted at step 2130.The base station also sends the wireless terminal an indication of whena new packet in a packet transmission sequence is being sent for theparticular assignment at step 2135. In some embodiments, this indicationmay simply entail a single bit that is alternated between 0 and 1 eachtime a new packet is transmitted. For each assignment the base stationalso sends an identification of the particular sub-packet that is beingsent by the base station at step 2140, for example the first, second orthird sub-packet as described above. As well, the base stationidentifies the PHY profile at step 2145 including the UIUC and the CIDof the transmission.

If two single antenna spatial multiplexing capable wireless terminalsare selected as indicated at 2150 then the base station sends the PHYprofile (step 2170), the repetition coding indication (step 2152), theH-ARQ channel identification (step 2155), the packet sequence number(step 2160) and the sub-packet ID (step 2165) for each of the twowireless terminals. The two wireless terminals use different pilotpatterns during transmission to differentiate between the two wirelessterminals.

Embodiments of the invention directed to a non-MIMO Chase based H-ARQscheme will now be described based on FIG. 16. When utilizing non-MIMOChase based H-ARQ, the base station sends to the wireless terminal anindication of a total number of assignments to be performed at step2210, then for each assignment the base station indicates to thewireless terminal the duration of the assignment in the frame where theH-ARQ transmission is to be transmitted in the frame at step 2220. Thebase station sends a repetition coding indication at step 2230 of a typedescribed above. The base station also sends the wireless terminal anidentification of a H-ARQ channel upon which the encoded information forthe particular assignment is transmitted at step 2240. The base stationalso sends the wireless terminal a transmission count at step 2250,which is an indication of how many times the transmission has been sent.In some embodiments for each assignment the base station also sends thewireless terminal a PHY profile at step 2260, in the form of the UIUCand CID. There may also be additional padding bits in the transmissionto provide an integer number of bytes in the base station transmission.

Embodiments of the invention directed to a MIMO Chase based H-ARQ schemewill now be described based on FIG. 17. For MIMO Chase based H-ARQ, thebase station sends to the wireless terminal an indication of a totalnumber of assignments to be performed at step 2310, then for eachassignment the base station indicates to the wireless terminal theduration of the assignment in the frame where the H-ARQ transmission isto be transmitted in the frame at step 2320. For each assignment thebase station sends an indication that the up-link signal is to come froma dual antenna transmission capable wireless terminal or a collaborationof two single antenna spatial multiplexing capable wireless terminals atstep 2325. If a dual antenna transmission capable wireless terminal isselected as of step 2330 then the base station sends an indication ofwhether MIMO communication is performed using STTD or SM at step 2332.Following this indication the base station sends a repetition codingindication at step 2335. The base station sends the wireless terminalthe PHY profile at step 2350, including the UIUC and CID and a channelID used for the H-ARQ transmission for the particular assignment at step2340. The base station also sends the wireless terminal the transmissioncount at step 2345.

If two single antenna spatial multiplexing capable wireless terminalsare selected at step 2355 then the base station sends the PHY profile(step 2370), including the UIUC and CID, the repetition codingindication at step 2357, the H-ARQ channel identification (step 2360),and the indication of the transmission count (step 2365) for each of thetwo wireless terminals. The two wireless terminals use different pilotpatterns during transmission to differentiate between the two wirelessterminals.

The STC based H-ARQ communications are used with MIMO enabledcommunications systems using STC mode. For up-link STC based H-ARQ, theformat used for sending information to the wireless terminal isessentially the same as that for down-link STC based H-ARQ describedabove in FIG. 13, except that an indication of the location in the frameof where the H-ARQ transmission is to be transmitted is replaced with aduration of the H-ARQ transmission.

In some embodiments of the invention, the base station sends thewireless terminal the information described above for MIMO or non-MIMOIR based H-ARQ and/or MIMO or non-MIMO Chase based H-ARQ and/or STCbased H-ARQ in the form of an IE that could be transmitted by the basestation in a portion of a data frame such as the up-link mappingcomponent 214 of the data frame of FIG. 6. Tables 6-10 below areparticular examples of formats for such IE.

In some embodiments of MIMO or non-MIMO IR based H-ARQ and/or MIMO ornon-MIMO Chase based H-ARQ as well as STC based H-ARQ, the base stationmay also send the wireless terminal an indication of the type of IE thatthe base station is sending, namely MIMO or non-MIMO IR based H-ARQand/or MIMO or non-MIMO Chase based H-ARQ and/or STC based H-ARQ. Thisindication of the type of IE may be in the form of an Extended UIUC.

IR_H-ARQ MAP IE

The following is an example of a format of an up-link IE that may beused in an up-link mapping component such as 214 of FIG. 6. This IE istransmitted by a base station to one or multiple wireless terminals thatare running H-ARQ enabled connections and using IR mode.

TABLE 6 IR_H-ARQ MAP IE Size Syntax (bits) Note IR_H-ARQ_IE( ) ExtendedUIUC 4 IR_H-ARQ = 0x09 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { UIUC 4 CID 16 Duration 10 Repetitioncoding 2 indication ACID 3 H-ARQ channel ID Packet_SN 1 Packet sequencenumber. When changed, it means a new packet is been transmitted SPID 2Sub-packet ID } Padding bits Variable Padding bits to align boundary ofbyte }

Most of the fields of the up-link “IR_H-ARQ MAP” IE have been previouslyabove with respect to the down-link “IR_H-ARQ MAP” IE.

Instead of having the Extended DUIC, the up-link IEs have an ExtendedUIUC (up-link interval usage code). The “Extended UIUC” field is used toassociate a code value to identify a particular type of IE. For example,the “IR_H-ARQ” IE in Table 6 has an “Extended UIUC”=09. Other IEdescribed below are indicated to have different respective Extended UIUCvalues. The values provided in Table 6 or subsequent tables below aremere examples of code values that could be used and it is to beunderstood that the code values assigned, and the number of bits used torepresent the codes values could be varied according to a desired usage.

In a UL mapping, a MIMO-enabled base station transmits an UIUC equal toa predefined value, to indicate a type of transmission format, forexample a coding scheme of the subsequent up-link allocation to aspecific wireless terminal CID for each assignment of a total number ofassignments.

Instead of the positional information needed in the down-link IEs, suchas “OFDMA Symbol offset”, “Subchannel offset”, “No. of OFDMA symbols”,“No. of subchannels” and “Boosting” fields, the “IR_H-ARQ MAP” IEindicates the size of the assignment by a “Duration” field. As theup-link sub-frame includes a series of essentially concatenated slots,only the duration or length of the slot is used for each assignment ofthe total number of assignments.

Chase_H-ARQ MAP IE

The following is an example of a format of an up-link IE that may beused in an up-link mapping component such as 214 of FIG. 6. This IE istransmitted by a base station to one or multiple wireless terminals thatare running H-ARQ enabled connections and using Chase mode.

TABLE 7 Chase_H-ARQ MAP IE Size Syntax (bits) Note Chase_H-ARQ_IE( )Extended UIUC 4 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { UIUC 4 CID 16 Duration 6 Repetition coding2 indication ACID 3 H-ARQ channel ID Tx_Count 2 Transmission count: 00:first transmission 01: second transmission 10: third transmission 11:fourth transmission } Padding bits Variable Padding bits to alignboundary of byte }

The up-link “Chase_H-ARQ MAP” IE is essentially the same as the up-link“IR_H-ARQ MAP° IE, except for replacing the “Packet_SN” and “SPID”fields with the “”Tx_Count” field.

Similar to the up-link “IR_H-ARQ MAP” IE, the positional information ofthe “Chase_H-ARQ MAP” IE is replaced with a “Duration” field.

MIMO_IR_H-ARQ MAP IE

The following is an example of a format of an up-link IE that may beused in an up-link mapping component such as 214 of FIG. 6. This IE istransmitted by a base station to one or multiple MIMO-capable wirelessterminals that are running H-ARQ enabled connections and using IR mode.

TABLE 8 MIMO_IR_H-ARQ MAP IE Size Syntax (bits) Note MIMO_IR_ H-ARQ_IE() Extended UIUC 4 Length 4 Num_Assignments 2 For i=0;i<Num_Assignments;i++) { Duration 10 Collaborative SM 1 0: Non collaborative _IndicationSM (assignment to a dual transmission capable wireless terminal) 1:Collaborative SM (assignment to 2 collaborative SM capable wirelessterminals) If ( Collaborative SM _Indication == 0) { MIMO_Control 1 0:STTD 1: SM CID 16 Connection ID UIUC 4 Repetition 2 coding indicationACID 3 H-ARQ channel ID Packet_SN 1 Packet sequence number. Whenchanged, it means a new packet is been transmitted SPID 2 Sub-packet ID} else {  CID 16 Connection ID. This wireless terminal shall use pilotpattern A  UIUC 4  Repetition 2 coding indication  ACID 3 H-ARQ channelID  Packet_SN 1 Packet ID-packet sequence number. When changed, it meansa new packet is been transmitted  SPID 2 Sub-packet ID  CID 16Connection ID. This wireless terminal shall use pilot pattern B  UIUC 4 ACID 3 H-ARQ channel ID  Packet_SN 1 Packet sequence number. Whenchanged, it means a new packet is been transmitted  SPID 2 Sub-packet ID} Padding bits Variable Padding bits to align boundary of byte }

In the “MIMO_IR_H-ARQ MAP” IE after a “For” loop for each assignment ofthe total number of assignments a “Duration” field indicates the size ofan assigned slot of the up-link sub-frame of the frame.

A “Collaborative SM_Indication” field indicates whether a single dualtransmission capable wireless terminal is to transmit information backto the base station or in each assignment or two collaborative spatialmultiplexing (SM) capable wireless terminals are each transmittinginformation back to the base station.

An “If . . . else” condition is used for the IE to provide particularsfor each of the two possible configurations. If a single dualtransmission capable wireless terminal is used, a “MIMO_Control” fieldindicates a type of transmission diversity to be used by the singlewireless terminal, for example STTD or SM. The remainder of the firstportion of the “If . . . else” condition contains fields similar to thepreviously described IEs.

If two collaborative wireless terminals are used, for each of the twowireless terminals the IE uses the “CID”, “UIUC”, “ACID”, “Packet_SN”and “SPID” fields that are similar to the other previously describedIEs. However, in this case the “CID” of the first wireless terminal ofthe two wireless terminals uses a first pilot pattern and the secondwireless terminal of the two wireless terminals uses a second pilotpattern.

MIMO_CHASE_H-ARQ MAP IE

The following is an example of a format of an up-link IE that may beused in an up-link mapping component such as 214 of FIG. 6. This IE istransmitted by a base station to one or multiple MIMO-capable wirelessterminal that are running H-ARQ enabled connections and using Chasemode.

TABLE 9 MIMO_Chase_H-ARQ MAP IE Size Syntax (bits) Note MIMO_Chase_H-ARQ_IE( ) Extended UIUC 4 Length 4 Num_Assignments 2 Fori=0;i<Num_Assignments;i+ +) { Duration 10 Collaborative SM 1 0: Noncollaborative _Indication SM (assignment to a dual transmission capablewireless terminal) 1: Collaborative SM (assignment to 2 collaborative SMcapable wireless terminals) If (Collaborative SM _Indication == 0) {MIMO_Control 1 0: STTD 1: SM CID 16 Connection ID UIUC 4 Repetitioncoding 2 indication ACID 3 H-ARQ channel ID Tx_Count 2 Transmissioncount: 00: first transmission 01: second transmission 10: thirdtransmission 11: fourth transmission } else {  CID 16 Connection ID.This wireless terminal shall use pilot pattern A  UIUC 4  Repetitioncoding 2 indication  ACID 3 H-ARQ channel ID  Tx_Count 2 Transmissioncount: 00: first transmission 01: second transmission 10: thirdtransmission 11: fourth transmission  CID 16 Connection ID. Thiswireless terminal shall use pilot pattern B  UIUC 4  Repetition coding 2indication  ACID 3 H-ARQ channel ID  Tx_Count 2 Transmission count: 00:first transmission 01: second transmission 10: third transmission 11:fourth transmission } Padding bits Variable Padding bits to alignboundary of byte }

The fields of the up-link “MIMO_Chase_H-ARQ MAP” IE are essentially thesame as the “MIMO_IR_H-ARQ MAP IE”, the exception that the “Packet_SN”and “SPID” fields of the IR based IE are replaced with the “Tx_Count”field.

STC_H-ARQ MAP IE

The following is an example of a format of an up-link IE that may beused in an up-link mapping component such as 214 of FIG. 6. This IE istransmitted by a base station to one or multiple dual-transmissioncapable wireless terminals that are running H-ARQ enabled connectionsand using STC mode. Examples of re-transmission matrices used are foundin Section 8.4.8.9 of IEEE standard P802.16e/D9 (June 2005).

TABLE 10 STC_H-ARQ MAP IE Size Syntax (bits) Note STC_H-ARQ_IE( )Extended UIUC 4 Length 4 Num_Assignments 2 For(i=0;i<Num_Assignments;i++) { UIUC 4 CID 16 Tx_Count 2 Transmissioncount: 00: first transmission 01: second transmission 10: thirdtransmission 11: fourth transmission If (Tx_Count == 00) { Duration 10Boosting 3 Repetition coding 2 indication } ACID 3 H-ARQ channel ID  }Padding bits Variable Padding bits to align boundary of byte }

For up-link STC based H-ARQ the format of the IE is the same as that fordown-link STC based H-ARQ described above.

The values in the “Size” column of Tables 1-10 refer to a number of bitsused to represent the element of each respective field. It is to beunderstood that these values are but one example for each respectivefield. In some embodiments, the number of bits can be greater or lessthan what is represented in Tables 1-10. For example, the number of bitsin any of the fields may be desired to be less than the valuesrepresented above to reduce an overall IE size, and therefore reduce anoverall overhead of the frame. Conversely, the number of bits in any ofthe fields may be greater than the values represented above at anacceptable cost of increasing the overall overhead of the frame.

Resource Management Protection

As described above, the IEEE 802.16(e) draft version of standard has noviable format for protecting resources from being abused by a maliciouswireless terminal who is not registered with the network, but cannone-the-less request transmission resources from the base station. FIG.18 shows a data frame, generally indicated at 900, similar to the dataframe of FIG. 6, but not showing all the same components as FIG. 6. Adown-link mapping component (DL MAP) 912 includes mapping IEs 913A and913B. An up-link mapping component (UL MAP) 914 includes mapping IEs915A and 915B. The data frame 900 also includes a down-link subframe 917containing down-link regions 918 allocated for transmissions from thebase station to the wireless terminal and an up-link subframe 919containing up-link slots 920,921 allocated for transmissions from thewireless terminal to the base station. Up-link mapping IE 915A acts as apointer to a first slot 920 of the up-link subframe 919 allocated forthe wireless terminal to request initial access to the network. Up-linkmapping IE 915B acts as a pointer to a second slot 921 of the up-linksubframe 919 allocated for the wireless terminal to request additionalup-link transmission resources, such as a BW request.

FIG. 19 shows a data frame, generally indicated at 1000, similar to thatof FIG. 18 with an improvement to aid in protecting the transmissionresources allocated by the base station. A down-link mapping component(DL MAP) 1012 includes non-encrypted mapping IEs 1013A,1013B,1013C. Afirst up-link mapping component (UL MAP) 1014 includes non-encryptedmapping IEs 1015A,1015B. A second UL MAP 1010 includes encrypted mappingIEs 1011A,1011B. Similar to FIG. 18, the data frame 1000 of FIG. 19 hasa down-link subframe 1017 having regions 1018 and an up-link subframe1019 having regions or slots 1020,1021. The DL MAP 1012 is used as aroot MAP for a purpose of initial network access. In some embodiments,the non-encrypted mapping IEs 1013A,1013B,1013C of the root MAP, DL MAP1012, act as pointers to another DL MAP or to an UL MAP. The another DLMAP may be an encrypted DL MAP or an non-encrypted DL MAP. Similarly,the UL MAP may be non-encrypted or encrypted, such as UL MAPs 1014 or1010, respectively. In some embodiments, one or more of non-encryptedmapping IEs 1013A,1013B,1013C of the root MAP, DL MAP 1012, act as apointer to a DL region, such as DL region 1018 in DL subframe 1017 or ULslots 1020,1021 in the UL subframe 1019. In some embodiments, one ormore of non-encrypted mapping IEs 1013A,1013B,1013C of the root MAP 1012act as a pointer to IEs 1015A,1015B in the first UL MAP 1014. IEs1015A,1015B of the first UL MAP 1014 may then act as pointers to the DLregion, such as DL region 1018 in DL subframe 1017 or the UL slot, suchas UL slot 1020,1021 in the UL subframe 1019. In some embodiments, oneor more of non-encrypted mapping IEs 1013A,1013B,1013C of the root MAP1012 act as a pointer to IEs 1011A,1011B in the second UL MAP 1010. IEs1011A,1011B of the second UL MAP 1010 may then act as pointers to the DLregion, such as DL region 1018 in DL subframe 1017 or the UL slot in theUL subframe 1019. In addition to being used for transmission of datafrom the base station to the wireless terminals, the DL regions 1018 areused for providing system configuration information such as DL or ULchannel description. Similarly, the UL slots 1020,1021 may be used forinitial ranging for aiding in initial network access and/or forindicating DL or UL resource allocation in addition to transmittinggeneral information from the wireless terminal to the base station.

The DL MAP 1012 acting as the root MAP includes non-encryptedinformation that any wireless terminal can understand without havingpre-acquired an encryption key. Encrypted information, for example insecond UL MAP 1010 is understandable only by wireless terminalsauthenticated by the base station to be registered with the network.

As described with relation to FIG. 6, the illustrated frame structure ofFIG. 19 is a specific example. The frame components such as the DL MAPand UL MAPs, DL subframe and UL subframe, as well as those not shownsuch as the preamble, may be implemented using an implementationspecific number of OFDM symbols, with implementation specific guardbands. The number and definition of OFDM subchannels is also animplementation detail. The layout sequence of the various fields canalso be varied.

A public access Traffic Encryption Key (TEK) for enabling encrypting theDL/UL MAPs is transmitted by the base station to the wireless terminalsregistered with the network at an authentication/authorization stage ofinitial network entry. The public access TEK is known to the basestation and any wireless terminals authenticated to be registered withthe network. Wireless terminals that are not authenticated as beingregistered with the network, do not receive the public access TEK and asa result can not decrypt the messages indicating the location in theframe allocated for requesting additional UL resources. In someembodiments, the public access key is periodically updated.

In some embodiments, the renewal and delivery of the public access keyis similar to that currently defined for MBS (multicast/broadcastservice). However, other techniques that are different than MBS areconsidered to be within the scope of the invention.

By implementing such an enhancement, the wireless terminal that isregistered with the network performs initial network access by readingthe non-encrypted root MAP 1012 for non-authenticated wireless terminalsand proceeds to the authentication stage. At the authentication stagethe registered wireless terminal obtains a TEK for each service flow anda public message key for encryption of selective management messages.Following this, the registered wireless terminal having passedauthentication and/or authorization procedures is capable of decryptingall encrypted DL or UL MAPs. A malicious wireless terminal that has notpassed the authentication and/or authorization procedures, cannotdecrypt the encrypted mapping component messages and therefore cannotdetermine appropriate UL resource allocation for sending an UL BWrequest code. Therefore, there is no chance for the malicious wirelessterminal to send a BW request header and disrupt and/or slow down thenetwork with pointless requests.

In some embodiments of the invention, a method is provided, as shown ina flow chart of FIG. 20 for resource management of resources in anetwork. At step 1110, a data frame is transmitted by the base stationproviding a first non-encrypted mapping message readable by any wirelessterminal, including a pointer to a second non-encrypted mapping messageused for initial network access. This second non-encrypted mappingmessage is also readable by any wireless terminal. The firstnon-encrypted mapping message may also include a pointer to an encryptedmapping message used to identify a location in the data frame forrequesting transmission resources, this encrypted mapping message beingreadable only by wireless terminals that are authenticated to beregistered with the network.

At step 1120, the wireless terminal receives the first non-encryptedmapping message and uses the pointer to the second non-encrypted mappingmessage to locate the second non-encrypted mapping message. The secondnon-encrypted mapping message includes a pointer to a location in theup-link subframe of the data frame for the wireless terminal to requestinitial access to the network. When the wireless terminal has receivedthe first non-encrypted mapping message and located the secondnon-encrypted mapping message, the wireless terminal requests access tothe network at step 1130, for example by transmitting a request to thebase station in a portion of the up-link subframe identified by thesecond non-encrypted mapping message. The base station authenticatesthat the wireless terminal is a registered wireless terminal with thenetwork, grants the wireless terminal's request for access to thenetwork, and sends the wireless terminal a public access encryption keyat step 1140.

Using the received encryption key, the wireless terminal is then able todecrypt an encrypted mapping message sent by the base station at step1150. The encrypted mapping message comprises a pointer to a slot in theup-link subframe of the data frame allocated by the base station to beused by the wireless terminal for requesting additional transmissionresources from the base station. The wireless terminal uses thedecrypted information to make a request for further up-link transmissionresources at step 1160.

While the above resource management protection scheme is described as anexample with respect to the wireless terminal requesting additionalbandwidth resources (BW request), it is to be understood that otherfacets of communication between the base station and the wirelessterminal may lend themselves to using such a resource managementprotection scheme and it is therefore within the scope of the inventionthat the described resource management protection scheme can be usedwherever such a scheme is needed for transmissions between the basestation and the wireless terminal.

Numerous modifications and variations of the present invention arepossible in light of the above teachings. It is therefore to beunderstood that within the scope of the appended claims, the inventionmay be practised otherwise than as specifically described herein.

1-28. (canceled)
 29. A method, comprising: at a first electronic deviceoperating a hybrid automatic repeat request (H-ARQ) enabled OrthogonalFrequency Division Multiplexing (OFDM) connection with a secondelectronic device: generating a control channel comprising at least oneindicator; and transmitting, to the second electronic device, thecontrol channel indicating a downlink H-ARQ transmission of two codingstreams using spatial multiplexing on an indicated resource, wherein theat least one indicator provides information comprising, a precodingmatrix used in the transmission of the two coding streams on theindicated resource, a mapping of the coding streams to correspondingtransmission layers, and a H-ARQ channel for each of the coding streams.30. The method of claim 29, wherein the information further comprises anumber of times the precoding matrix was used.
 31. The method of claim29, wherein the information further comprises a signal power of thedownlink H-ARQ transmission.
 32. The method of claim 29, wherein themapping of the coding streams to corresponding transmission layerscomprises a physical (PHY) profile in a form of at least one of adown-link usage interval code (DICU) or a connection identification(CID).
 33. The method of claim 29, wherein the H-ARQ transmissionutilizes one of an incremental redundancy (IR) based H-ARQ, a Chasebased H-ARQ, or a space-timing code combining (STC) based H-ARQ.
 34. Afirst electronic device, comprising: a baseband processor; and atransceiving circuitry operatively connected to the baseband processor,wherein the baseband processor and the transceiving circuitry areconfigured for operating a hybrid automatic repeat request (H-ARQ)enabled Orthogonal Frequency Division Multiplexing (OFDM) connectionwith a second electronic device by: generating a control channelcomprising at least one indicator; and transmitting, to the secondelectronic device, the control channel indicating a downlink H-ARQtransmission of two coding streams using spatial multiplexing on anindicated resource, wherein the at least one indicator providesinformation comprising, a precoding matrix used in the transmission ofthe two coding streams on the indicated resource, a mapping of thecoding streams to corresponding transmission layers, and a H-ARQ channelfor each of the coding streams.
 35. The first electronic device of claim35, wherein the information further comprises a number of times theprecoding matrix was used.
 36. The first electronic device of claim 35,wherein the information further comprises a signal power of the downlinkH-ARQ transmission.
 37. The first electronic device of claim 35, whereinthe mapping of the coding streams to corresponding transmission layerscomprises a physical (PHY) profile in a form of at least one of adown-link usage interval code (DICU) or a connection identification(CID).
 38. The first electronic device of claim 35, wherein the H-ARQtransmission utilizes one of an incremental redundancy (IR) based H-ARQ,a Chase based H-ARQ, or a space-timing code combining (STC) based H-ARQ.39. The first electronic device of claim 35, wherein the firstelectronic device is a base station and the second electronic device isa wireless terminal.
 40. An integrated circuit in a first electronicdevice operating a hybrid automatic repeat request (H-ARQ) enabledOrthogonal Frequency Division Multiplexing (OFDM) connection withanother electronic device, comprising: circuitry to generate a controlchannel comprising at least one indicator; and circuitry to transmit, tothe another electronic device, the control channel indicating a downlinkH-ARQ transmission of two coding streams using spatial multiplexing onan indicated resource, wherein the at least one indicator providesinformation comprising, a precoding matrix used in the transmission ofthe two coding streams on the indicated resource, a mapping of thecoding streams to corresponding transmission layers, and a H-ARQ channelfor each of the coding streams.
 41. The integrated circuit of claim 40,wherein the information further comprises a number of times theprecoding matrix was used.
 42. The integrated circuit of claim 40,wherein the information further comprises a signal power of the downlinkH-ARQ transmission.
 43. The integrated circuit of claim 40, wherein themapping of the coding streams to corresponding transmission layerscomprises a physical (PHY) profile in a form of at least one of adown-link usage interval code (DICU) or a connection identification(CID).
 44. The integrated circuit of claim 40, wherein the H-ARQtransmission utilizes one of an incremental redundancy (IR) based H-ARQ,a Chase based H-ARQ, or a space-timing code combining (STC) based H-ARQ.45. The integrated circuit of claim 40, wherein the integrated circuitis included in a base station device.